20 research outputs found
Therapeutic targeting of cathepsin C::from pathophysiology to treatment
Cathepsin C (CatC) is a highly conserved tetrameric lysosomal cysteine dipeptidyl aminopeptidase. The best characterized physiological function of CatC is the activation of pro-inflammatory granule-associated serine proteases. These proteases are synthesized as inactive zymogens containing an N-terminal pro-dipeptide, which maintains the zymogen in its inactive conformation and prevents premature activation, which is potentially toxic to the cell. The activation of serine protease zymogens occurs through cleavage of the N-terminal dipeptide by CatC during cell maturation in the bone marrow. In vivo data suggest that pharmacological inhibition of pro-inflammatory serine proteases would suppress or attenuate deleterious effects of inflammatory/auto-immune disorders mediated by these proteases. The pathological deficiency in CatC is associated with Papillon-Lefèvre syndrome. The patients however do not present marked immunodeficiency despite the absence of active serine proteases in immune defense cells. Hence, the transitory pharmacological blockade of CatC activity in the precursor cells of the bone marrow may represent an attractive therapeutic strategy to regulate activity of serine proteases in inflammatory and immunologic conditions. A variety of CatC inhibitors have been developed both by pharmaceutical companies and academic investigators, some of which are currently being employed and evaluated in preclinical/clinical trials
Protéases à serine du neutrophile et inflammations pulmonaires : 1. L’air exhalé condensé est-il un matériel adapté pour les mesures d’activités protéolytiques ? : 2. La spécificité des protéases neutrophiliques valide-t-elle l’utilisation du modèle souris de Broncho-Pneumopathie Chronique Obstructive (BPCO) ?
Le recrutement des neutrophiles qui caractérise l’inflammation observée lors de différentes pathologies pulmonaires conduit à la libération dans le milieu extracellulaire de protéases à sérine qui sont en partie responsables de la dégradation du tissu pulmonaire et/ou de la chronicité de l’inflammation. L’objectif initial de cette thèse était de développer une méthode de quantification de ces protéases, à partir des condensats d’air exhalé. En dépit de la sensibilité de la technique nous n’avons pas été en mesure de détecter des quantités significatives de protéases actives dans ces condensats. Ces résultats négatifs ont néanmoins permis de confirmer des hypothèses sur la distribution des protéases dans le milieu extracellulaire. La deuxième partie des travaux a été consacrée à la validation du modèle souris exposée à la fumée de cigarette comme modèle animal de bronchopneumopathie chronique obstructive. Nous avons purifié les trois protéases à sérine du neutrophile murin et avons construit des nouveaux substrats sensibles et spécifiques à partir des informations fournies par des études de modélisation moléculaire. Ces nouveaux outils permettent de valider l’utilisation du modèle souris pour comprendre le rôle des protéases à sérine dans la génération de peptides chimiotactiques au cours de la BPCO.Neutrophils recruitment is a hallmark of the inflammation associated with different lung diseases. This recruitment leads to the release in the extracellular matrix of serine proteases that are responsible at least in part, of the degradation of the pulmonary tissue and/or of the chronicity of inflammation. The initial objective of this thesis was to develop a method of quantification of these proteases, based on the analysis of exhaled air condensate. But in spite of the sensitivity of the methods, we have not been able to detect any significant activity of neutrophil serine proteases in these condensates. This negative result however gave support a hypothesis we formulated on the extracellular biodistribution of proteases in lung secretions. The second part of this thesis was devoted to the validation of an animal model of chronic obstructive pulmonary disease, i.e. the mouse exposed to cigarette smoke. We have purified three murine serine neutrophil proteases and developed new sensitive and specific FRET substrates which were designed starting from molecular modeling studies. These new tools that validate the use of the mouse model of human COPD, will be of great help to understand the role of serine proteases for generating chemotactic peptides during this chronic disease
Protéases à serine du neutrophile et inflammations pulmonaires (1. L'air exhalé condensé est-il un matériel adapté pour les mesures d'activités protéolytiques ?)
Le recrutement des neutrophiles qui caractérise l inflammation observée lors de différentes pathologies pulmonaires conduit à la libération dans le milieu extracellulaire de protéases à sérine qui sont en partie responsables de la dégradation du tissu pulmonaire et/ou de la chronicité de l inflammation. L objectif initial de cette thèse était de développer une méthode de quantification de ces protéases, à partir des condensats d air exhalé. En dépit de la sensibilité de la technique nous n avons pas été en mesure de détecter des quantités significatives de protéases actives dans ces condensats. Ces résultats négatifs ont néanmoins permis de confirmer des hypothèses sur la distribution des protéases dans le milieu extracellulaire. La deuxième partie des travaux a été consacrée à la validation du modèle souris exposée à la fumée de cigarette comme modèle animal de bronchopneumopathie chronique obstructive. Nous avons purifié les trois protéases à sérine du neutrophile murin et avons construit des nouveaux substrats sensibles et spécifiques à partir des informations fournies par des études de modélisation moléculaire. Ces nouveaux outils permettent de valider l utilisation du modèle souris pour comprendre le rôle des protéases à sérine dans la génération de peptides chimiotactiques au cours de la BPCO.Neutrophils recruitment is a hallmark of the inflammation associated with different lung diseases. This recruitment leads to the release in the extracellular matrix of serine proteases that are responsible at least in part, of the degradation of the pulmonary tissue and/or of the chronicity of inflammation. The initial objective of this thesis was to develop a method of quantification of these proteases, based on the analysis of exhaled air condensate. But in spite of the sensitivity of the methods, we have not been able to detect any significant activity of neutrophil serine proteases in these condensates. This negative result however gave support a hypothesis we formulated on the extracellular biodistribution of proteases in lung secretions. The second part of this thesis was devoted to the validation of an animal model of chronic obstructive pulmonary disease, i.e. the mouse exposed to cigarette smoke. We have purified three murine serine neutrophil proteases and developed new sensitive and specific FRET substrates which were designed starting from molecular modeling studies. These new tools that validate the use of the mouse model of human COPD, will be of great help to understand the role of serine proteases for generating chemotactic peptides during this chronic disease.TOURS-Bibl.électronique (372610011) / SudocSudocFranceF
Measuring elastase, proteinase 3 and cathepsin G activities at the surface of human neutrophils with fluorescence resonance energy transfer substrates
The neutrophil serine proteases (NSPs) elastase, proteinase 3 and cathepsin G are multifunctional proteases involved in pathogen destruction and the modulation of inflammatory processes. A fraction of secreted NSPs remains bound to the external plasma membrane, where they remain enzymatically active. This protocol describes the spectrofluorometric measurement of NSP activities on neutrophil surfaces using highly sensitive Abz-peptidyl-EDDnp fluorescence resonance energy transfer (FRET) substrates that fully discriminate between the three human NSPs. We describe FRET substrate synthesis, neutrophil purification and handling, and kinetic experiments on quiescent and activated cells. These are used to measure subnanomolar concentrations of membrane-bound or free NSPs in low-binding microplates and to quantify the activities of individual proteases in biological fluids like expectorations and bronchoalveolar lavages. the whole procedure, including neutrophil purification and kinetic measurements, can be done in 4-5 h and should not be longer because of the lifetime of neutrophils. Using this protocol will help identify the contributions of individual NSPs to the development of inflammatory diseases and may reveal these proteases to be targets for therapeutic inhibitors.Alexander von Humboldt FoundationGerman Research CouncilVaincre la MucoviscidoseFundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)Proteases & Vectorisat Pulm Fac Med, INSERM, U618, F-37032 Tours, FranceMax Planck Inst Neurobiol, Dept Neuroimmunol, D-82152 Planegg Martinsried, GermanyUniv Tours, F-37032 Tours, FranceUniversidade Federal de São Paulo, Escola Paulista Med, Dept Biofis, BR-0404420 São Paulo, BrazilINSERM, U921, F-37032 Tours, FranceUniversidade Federal de São Paulo, Escola Paulista Med, Dept Biofis, BR-0404420 São Paulo, BrazilWeb of Scienc
Proteomics of exhaled breath: methodological nuances and pitfalls
Background: The analysis of exhaled breath condensate (EBC) can be an alternative to traditional endoscopic sampling of lower respiratory tract secretions. This is a simple non-invasive method of diagnosing respiratory diseases, in particular, respiratory inflammatory processes. Methods: Samples were collected with a special device-condenser (ECoScreen, VIASYS Healthcare, Germany), then treated with trypsin according to the proteomics protocol for standard protein mixtures and analyzed by nanoflow high-performance liquid chromatography tandem mass spectrometry (HPLC-MS/MS) with a 7-Tesla Finnigan LTQ-FT mass spectrometer (Thermo Electron, Germany). Mascot software (Matrixscience) was used for screening the database NCBInr for proteins corresponding to the peptide maps that were obtained. Results: EBCs from 17 young healthy non-smoking donors were collected. Different methods for concentrating protein were compared in order to optimize EBC preparations for proteomic analysis. The procedure that was chosen allowed identification of proteins exhaled by healthy people. The major proteins in the condensates were cytoskeletal keratins. Another 12 proteins were identified in EBC from healthy non-smokers. Some keratins were found in the ambient air and may be considered exogenous components of exhaled air. Conclusions: Knowledge of the normal proteome of exhaled breath allows one to look for biomarkers of different disease states in EBC. Proteins in ambient air can be identified in the respiratory tract and should be excluded from the analysis of the proteome of EBC. The results obtained allowed us to choose the most effective procedure of sample preparation when working with samples containing very low protein concentrations. Clin Chem Lab Med 2009;47:706–12.Peer Reviewe
Spatially Resolved Monitoring of Neutrophil Elastase Activity with Ratiometric Fluorescent Reporters
Structural Characterization of Mouse Neutrophil Serine Proteases and Identification of Their Substrate Specificities: RELEVANCE TO MOUSE MODELS OF HUMAN INFLAMMATORY DISEASES*
It is widely accepted that neutrophil serine proteases (NSPs) play a critical role in neutrophil-associated lung inflammatory and tissue-destructive diseases. To investigate NSP pathogenic role(s), various mouse experimental models have been developed that mimic acutely or chronically injured human lungs. We and others are using mouse exposure to cigarette smoke as a model for chronic obstructive pulmonary disease with or without exacerbation. However, the relative contribution of NSPs to lung disease processes as well as their underlying mechanisms remains still poorly understood. And the lack of purified mouse NSPs and their specific substrates have hampered advances in these studies. In this work, we compared mouse and human NSPs and generated three-dimensional models of murine NSPs based on three-dimensional structures of their human homologs. Analyses of these models provided compelling evidence that peptide substrate specificities of human and mouse NSPs are different despite their conserved cleft and close structural resemblance. These studies allowed us to synthesize for the first time novel sensitive fluorescence resonance energy transfer substrates for individual mouse NSPs. Our findings and the newly identified substrates should better our understanding about the role of NSPs in the pathogenesis of cigarette-associated chronic obstructive pulmonary disease as well as other neutrophils-associated inflammatory diseases
Cathepsin G and Neutrophil Elastase Play Critical and Nonredundant Roles in Lung-Protective Immunity against Streptococcus pneumoniae in Mice ▿
Neutrophil serine proteases cathepsin G (CG), neutrophil elastase (NE), and proteinase 3 (PR3) have recently been shown to contribute to killing of Streptococcus pneumoniae in vitro. However, their relevance in lung-protective immunity against different serotypes of S. pneumoniae in vivo has not been determined so far. Here, we examined the effect of CG and CG/NE deficiency on the lung host defense against S. pneumoniae in mice. Despite similar neutrophil recruitment, both CG knockout (KO) mice and CG/NE double-KO mice infected with focal pneumonia-inducing serotype 19 S. pneumoniae demonstrated a severely impaired bacterial clearance, which was accompanied by lack of CG and NE but not PR3 proteolytic activity in recruited neutrophils, as determined using fluorescence resonance energy transfer (FRET) substrates. Moreover, both CG and CG/NE KO mice but not wild-type mice responded with increased lung permeability to infection with S. pneumoniae, resulting in severe respiratory distress and progressive mortality. Both neutrophil depletion and ablation of hematopoietic CG/NE in bone marrow chimeras abolished intra-alveolar CG and NE immunoreactivity and led to bacterial outgrowth in the lungs of mice, thereby identifying recruited neutrophils as the primary cellular source of intra-alveolar CG and NE. This is the first study showing a contribution of neutrophil-derived neutral serine proteases CG and NE to lung-protective immunity against focal pneumonia-inducing serotype 19 S. pneumoniae in mice. These data may be important for the development of novel intervention strategies to improve lung-protective immune mechanisms in critically ill patients suffering from severe pneumococcal pneumonia